Plant Genes, Genomes and Genetics provides a dedicated, plant focused textbook for graduates and advanced undergraduates. The book considers the control of plant gene expression in the broad sense from the mechanism of transcription to the generation of a protein and will provide a general idea of how these processes occur in plants, specifically highlighting cases when plants and other organisms are different. Plant gene expression continues to be taught from general textbooks that focus primarily on yeast and animals for eukaryotes, yet rarely mention plants so this book aims to fill that gap in teaching material. This book will be the first book in the Wiley-Blackwell/ASPB Plant Biology Book Series.

Plant Genes, Genomes and Genetics takes into account various dimensions of plants genes and genomes along with the brief description on breeding systems in plants. It includes the meaning of genetic and physiological control in plants, plant genotype and clonal breeding in plants. Provide the reader with the insights into the development of genetics and genomes amongst plants, so as to understand those situations referring to when and how plants operate differently from other organisms.

While the complete sequencing of the genomes of model organisms such as a multitude of bacteria and archaea, the yeast Saccharomyces cerevisiae, the worm Caenorhabditis elegans, the fly Drosophila melanogaster, and the mouse and human genomes have received much public attention, the deciphering of plant genomeswas greatly lagging behind. Up to now, only two plant genomes, one of the model plant Arabidopsis thaliana and one of the crop species rice (Oryza sativa) have been sequenced, though a series of other crop genome sequencing projects are underway. Notwithstanding this public bias towards genomics of animals and humans, it is nevertheless of great importance for basic and applied sciences and industries in such diverse fields as agriculture, breeding in particular, evolutionary genetics, biotechnology, and food science to know the composition of crop plant genomes in detail. It is equally crucial for a deeper understanding of the molecular basis of biodiversity and synteny. The Handbook of Genome Mapping: Genetic and Physical Mapping is the first book on the market to cover these hot topics in considerable detail, and is set apart by its combination of genetic and physical mapping. Throughout, each chapter begins with an easy-to-read introduction, also making the book the first reference designed for non-specialists and newcomers, too. In addition to being an outstanding bench work reference, the book is an excellent textbook for learning and teaching genomics, in particular for courses on genome mapping. It also serves as an up-to-date guide for seasoned researchers involved in the genetic and physical mapping of genomes, especially plant genomes.

Plant molecular biology came to the fore in the early 1980s and there has been tremendous growth in the subject since then. The study of plant genes and genomes, coupled with the development of techniques for the incorporation of novel or modified genes into plants, eventually led to the commercialisation of genetically modified (GM) crops in the mid-1990s. This was seen as the start of a biotechnological revolution in plant breeding. However, plant biotechnology became one of the hottest debates of the age and, in Europe at least, has been mired in controversy and over-regulation. Nevertheless, recent years have seen further technological innovation in the development of a range of techniques that enable scientists to make specific changes to target genes. Through a detailed history and development of the science and techniques that underpin crop biotechnology, this title is concise, comprehensive and readable. As well as new sections on genome editing, this edition includes expanded sections on current GM crops and future developments in plant biotechnology, and updated sections on techniques, legislation and the GM crop debate. The previous edition of this book, titled Genetically Modified Crops, 2nd Edition, was published in November 2011. Contents: DNA, Genes, Genomes and Plant BreedingThe Techniques of Plant Genetic Modification and Genome EditingThe Use of Genetically Modified (GM) and Genome-edited Crops in AgricultureLegislation Covering Genetically Modified (GM) Crops and FoodsIssues that Have Arisen in the GM Crop and Food Debate Readership: It is accessible to a general readership with a scientific background but also provides useful information for the specialist, particularly those interested in the production of genetically modified (GM) and genome edited crops, the use of GM and genome edited crops in commercial agriculture. Keywords: Agriculture;Agricultural Sciences;Biology;Biotechnology;Botany;Crop Science;Environment;Food;Genes;Genetics; Genetic Engineering;Genetic Modification;Genetic Manipulation;GM Crops;Plant Breeding;PlantsReview: Key Features: Written by an acknowledged expert in the fieldNow includes genome edited as well as GM cropsGreatly expanded sections on current GM and genome edited crops and future developments in plant biotechnologyUpdated sections on legislation and the GM crop debateA concise reference with all the important facts in one placeA readable treatise of an issue with implications for science in society that go well beyond plant breeding and crop science

Rapid advances in a collection of techniques referred to as gene technology, genetic engineering, recombinant DNA technology and gene cloning have pushed molecular biology to the forefront of the biological sciences.

How do we know what role a particular gene has? How do some genes control the expression of others? How do genes interact to form gene networks? With its unique integration of genetics and molecular biology, Genetic Analysis probes fascinating questions such as these, detailing how our understanding of key genetic phenomena can be used to understand biological systems. Opening with a brief overview of key genetic principles, model organisms, and epigenetics, the book goes on to explorethe use of gene mutations and the analysis of gene expression and activity. A discussion of the genetic structure of natural populations follows, before the interaction of genes during suppression and epistasis, how we study gene networks, and personalized genomics are considered. Drawing on the latest experimental tools, including microarrays, RNAi screens, and bioinformatics approaches, Genetic Analysis provides a state-of-the-art review of the field, but in a truly student-friendly manner. It uses extended case studies and text boxes to augment the narrative, taking the reader right to the forefront of contemporary research, without losing clarity of explanation and insight. We are in an age where, despite knowing so much about biological systems, we are just beginning to realise how much more there is still to understand. Genetic Analysis is the ideal guide to how we can use the awesome power of molecular genetics to further our understanding. Online Resource Centre: The Online Resource Centre to accompany Genetic Analysis features the following resources for teachers and students: For students: * Topical updates - key updates on topics or tools presented in the book, to keep you up-to-date with the latest developments in the field. * Additional case studies and text boxes to complement and add to those found in the book. * Practice problems, to test the reader's knowledge of the concepts presented, and help to master them. For registered adopters ofthe book: * Figures from the book in electronic format, ready to download. * Journal clubs - suggested papers and discussion questions linked to topics covered in the book.

Genetic material is in flux: this is one of the most exciting recent concepts in molecular biology. This volume of "Plant Gene Research" describes changes that occur in the genetic material of plants. It is worthwhile re membering that the first examples of unstable genomes were described for maize before DNA was known to be the genetic material. Now trans posable elements like the ones found in maize have been described in almost all organisms and have become incorporated into our thinking about genome structure. Flux in the plant genome is not restricted to transposable elements or to nuclear genes. Exchanges of genetic material have been demonstrated within organelle DNA, between organelle DNAs or between organelle and nuclear DNAs. Such exchanges may only occur over evolutionary times or may be a continuing process. Also the environment alters the plant genome. Stress, either viral, nutri tional or tissue-culture induced causes heritable changes in the genome. Infection with the crown gall bacterium Agrobacterium tumefaciens results in the transfer of bacterial DNA into the plant genome.

Targeted at beginners as well as experienced users, this handy reference explains the benefits and uses of flow cytometery in the study of plants and their genomes. Following a brief introduction that highlights general considerations when analyzing plant cells by flow cytometric methods, the book goes on to discuss examples of application in plant genetics, genomic analysis, cell cycle analysis, marine organism analysis and breeding studies. With its list of general reading and a glossary of terms, this first reference on FCM in plants fills a real gap by providing first-hand practical hints for the growing community of plant geneticists.

Recent advances that allow scientists to quickly and accurately sequence a genome have revolutionized our view of the structure and function of genes as well as our understanding of evolution. A new era of genetics is underway, one that allows us to fully embrace Dobzhansky's famous statement that "Nothing in biology makes sense except in the light of evolution". Genetics: Genes, Genomes, and Evolution presents the fundamental principles of genetics and molecular biology from an evolutionary perspective as informed by genome analysis. By using what has been learned from the analyses of bacterial and eukaryotic genomes as its basis, the book unites evolution, genomics, and genetics in one narrative approach. Genomic analysis is inherently both molecular and evolutionary, and every chapter is approached from this unified perspective. Similarly, genomic studies have provided a deeper appreciation of the profound relationships between all organisms - something reflected in the book's integrated discussion of bacterial and eukaryotic evolution, genetics and genomics. It is an approach that provides students with a uniquely flexible and contemporary view of genetics, genomics, and evolution. Online Resource Centre: - Video tutorials: a series of videos that provide deeper, step-by-step explanations of a range of topics featured in the text. - Flashcards: electronic flashcards covering the key terms from the text. For registered adopters of the text: - Digital image library: Includes electronic files in PowerPoint format of every illustration, photo, graph and table from the text - Lecture notes: Editable lecture notes in PowerPoint format for each chapter help make preparing lectures faster and easier than ever. Each chapter's presentation includes a succinct outline of key concepts, and incorporates the graphics from the chapter - Library of exam-style questions: a suite of questions from which you can pick potential assignments and exams. - Test bank of multiple-choice questions: a ready-made electronic testing resource that can be customized by lecturers and delivered via their institution's virtual learning environment. - Solutions to all questions featured in the book: solutions written by the authors help make the grading of homework assignments easier. - Journal Clubs: a series of questions that guide your students through the reading and interpretation of a research paper that relates to the subject matter of a given chapter. Each Journal club includes model answers for lecturers. - Instructor's guide: The instructor's guide discusses the educational approach taken by Genetics: Genes, Genomes, and Evolution in more detail, why this approach has been taken, what benefits it offers, and how it can be adopted in your class.